Pulse diffusion welding of female joints
- Authors: Strizhakov E.L.1, Nescoromniy S.V.1, Lyudmirsky Y.G.1, Mordovtsev N.A.1
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Affiliations:
- Don State Technical University
- Issue: No 3 (2024)
- Pages: 89-98
- Section: Articles
- URL: https://vektornaukitech.ru/jour/article/view/971
- DOI: https://doi.org/10.18323/2782-4039-2024-3-69-8
- ID: 971
Cite item
Abstract
Special feature of operation of electrovacuum tubes, in particular the cathode assembly, is constant heating due to bombardment of its surface with electrons. Stable characteristics and durability of the cathode assembly depend on high-quality connection (welding) of the core surfaces with the emitter over the entire area of the overlapped conjugation. The use of diffusion welding for joining a cathode assembly made of dissimilar materials is not possible due to the occurrence of poor welding fusion due to the presence of gaps in the ring sectors of the equipment, and, consequently, a decrease in the service life of the cathode assembly. The authors proposed to implement the process by combining magnetic pulse welding with diffusion welding. The originality of the work is the possibility of remote action on the joint through a dielectric quartz cup, which is a part of the technological vacuum chamber. The inductor system is outside the quartz cup, which allows heating the assembled unit without heating the tool – an inductor made of dissimilar materials – to a temperature of 700 ° C and higher. The authors determined the main parameters of the process of pulse diffusion welding in vacuum: pressure in the working chamber is В=0.66·10−2 Pa (5·10−5 mm Hg); preheating temperature is T=700–1250 °C; magnetic field pulse energy is W=5÷17 kJ; operating frequency of current pulse discharge is fd=5–15 kHz; magnetic pressure is Pm>∙107 N/m2. In this way, cathode assemblies of a wide range of metal pair combinations with a base diameter of d=20 mm and a sample length of L=40 mm were produced. The proposed technology has been successfully implemented and introduced at Tantal (Open Joint Stock company). The economic effect consists in reducing labor intensity and obtaining joints of stable quality.
About the authors
Evgeny L. Strizhakov
Don State Technical University
Email: strizhakov@inbox.ru
Doctor of Sciences (Engineering), Professor, leading researcher of the Center for Scientific Competencies
Russian Federation, 344010, Russia, Rostov-on-Don, Gagarin Square, 1Stanislav V. Nescoromniy
Don State Technical University
Author for correspondence.
Email: nescoromniy@mail.ru
ORCID iD: 0000-0003-0243-7241
PhD (Engineering), Associate Professor, Head of Chair “Machines and Automation of Welding Engineering”
Russian Federation, 344010, Russia, Rostov-on-Don, Gagarin Square, 1Yury G. Lyudmirsky
Don State Technical University
Email: lyudmirskiy40@mail.ru
Doctor of Sciences (Engineering), Professor, leading researcher of the Center for Scientific Competencies
Russian Federation, 344010, Russia, Rostov-on-Don, Gagarin Square, 1Nikolay A. Mordovtsev
Don State Technical University
Email: map642@mail.ru
graduate student
Russian Federation, 344010, Russia, Rostov-on-Don, Gagarin Square, 1References
- Kushpelev Yu.V. Diffusion welding in instrumentation. Vektor razvitiya, 2022, no. 11, pp. 72–83. EDN: JRIGAD.
- Barabanova O.A., Polunin V.A., Salmin P.A. Diffusion welding: possible defects of welded joints, reasons for their occurrence, and methods of control. Svarochnoe proizvodstvo, 2017, no. 10, pp. 34–43. EDN: YLXALK.
- Lyushinskiy A.V. Comparison of some methods of intensification of the diffusion welding process. Svarochnoe proizvodstvo, 2021, no. 12, pp. 22–29. EDN: JZWQSH.
- Zhang Jian Yang, Xu Bin, Naeemul Haq Tariq, Sun MingYue, Li DianZhong, Li Yi Yi. Microstructure evolutions and interfacial bonding behavior of Ni-based superalloys during solid state plastic deformation bonding. Journal of Materials Science & Technology, 2020, vol. 46, pp. 1–11. doi: 10.1016/j.jmst.2019.11.015.
- Chen Chang, Qian Sanfeng, Liu Rui, Wang Shan, Liao Bin, Zhong Zhihong, Cao Lingfei, Coenen Jan W., Wu Yucheng. The microstructure and tensile properties of W/Ti multilayer composites prepared by spark plasma sintering. Journal of Alloys and Compounds, 2019, vol. 780, pp. 116–130. doi: 10.1016/j.jallcom.2018.11.346.
- Shen Qiang, Xiang Huiying, Luo Guoqiang, Wang Chuanbin, Li Meijuan, Zhang Lianmeng. Microstructure and mechanical properties of TC4/oxygen-free copper joint with silver interlayer prepared by diffusion bonding. Materials Science and Engineering: A, 2014, vol. 596, pp. 45–51. doi: 10.1016/j.msea.2013.12.017.
- Ding Wen, Liu Ning, Fan Jiacheng, Cao Jing, Wang Xiaojing. Diffusion bonding of copper to titanium using CoCrFeMnNi high-entropy alloy interlayer. Intermetallics, 2021, vol. 129, article number 107027. doi: 10.1016/j.intermet.2020.107027.
- Shen Qiang, Xiang Huiying, Luo Quoqiang, Su Xiaopeng, Zhang Lianmeng. Interfacial microstructure and mechanical properties of diffusion bonded TC4/0Cr18Ni9/Oxygen Free Copper joints. Materials & Design, 2013, vol. 50, pp. 230–234. doi: 10.1016/j.matdes.2013.01.042.
- Aydın K., Kaya Y., Kahraman N. Experimental study of diffusion welding/bonding of titanium to copper. Materials & Design, 2012, vol. 37, pp. 356–368. doi: 10.1016/j.matdes.2012.01.026.
- Wei Yanni, Li Yaru, Zhu Linghao, Chen Yu, Guo Bingbing. Study on inhibition of interfacial compounds and improvement of joint properties by low temperature and high-pressure process in diffusion bonding of Ti/Cu. Vacuum, 2023, vol. 218, article number 112636. doi: 10.1016/j.vacuum.2023.112636.
- Feng Wei, Zhang Jian, Guo Hucheng, Xiao Yong, Luo Guoqiang, Shen Qiang. Dissimilar low-temperature diffusion bonding of copper and titanium using a Zn interlayer: Interfacial microstructure and mechanical properties. Intermetallics, 2024, vol. 173, article number 108437. doi: 10.1016/j.intermet.2024.108437.
- Klokova M.S., Ivanov I.A. Research on the production of bimetallic compounds by diffusion welding in a vacuum. Vakuumnaya tekhnika i tekhnologiya, 2017, vol. 27, no. 2, pp. 3.1–3.3. EDN: YVANOD.
- Strizhakov E.L., Nescoromniy S.V., Lyudmirskiy Yu.G., Mordovtsev N.A. Methods of magnetic pulse welding. Izvestiya Volgogradskogo gosudarstvennogo tekhnicheskogo universiteta, 2024, no. 2, pp. 70–77. doi: 10.35211/1990-5297-2024-2-285-70-77.
- Chernikov D.G., Yusupov R.Yu., Pesotskiy V.I., Alekhina V.K. Designs of assembly joints and magnetic-pulse technology for their implementation. Aerokosmicheskaya tekhnika i tekhnologii, 2023, vol. 1, no. 3, pp. 173–182. EDN: FFZSNM.
- Glushchenkov V.A. Magnetic pulse assembly technology in the production of bimetallic earthing. Kuznechno-shtampovochnoe proizvodstvo. Obrabotka materialov davleniem, 2019, no. 8, pp. 16–25. EDN: XQTGQY.
- Cherepnin Yu.S., Semenov A.N., Uvarov A.A. Development of the design and technology of diffusion welding of bimetallic cylindrical joints “austenitic steel – zirconium alloy”. Svarochnoe proizvodstvo, 2018, no. 9, pp. 16–19. EDN: YLVDFB.
- Sapanathan T., Raoelison R.N., Buiron N., Rachik M. Magnetic Pulse Welding: An Innovative Joining Technology for Similar and Dissimilar Metal Pairs. Industrial Engineering and Management. Joining Technologies, 2016, pp. 243–273. doi: 10.5772/63525.
- Angshuman Kapil, Abhay Sharma. Magnetic pulse welding: an efficient and environmentally friendly multi-material joining technique. Journal of Cleaner Production, 2015, vol. 100, pp. 35–58. doi: 10.1016/j.jclepro.2015.03.042.
- Chen Yingzi, Yang Zhiyuan, Peng Wenxiong, Zhang Huaiqing. Experimental investigation and optimization on field shaper structure parameters in magnetic pulse welding. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2021, vol. 235, no. 13, pp. 2108–2117. doi: 10.1177/09544054211014846.
- Zaytsev E., Krutikov V., Spirin A., Paranin S. Development of Multi-Part Field-Shapers for Magnetic Pulse Welding Using Nanostructured Cu-Nb Composite. Journal of Manufacturing and Materials Processing, 2024, vol. 8, no. 3, article number 97. doi: 10.3390/jmmp8030097.
- Ashish K. Rajak, Ramesh Kumar, Kore S.D. Designing of field shaper for the electro-magnetic crimping process. Journal of Mechanical Science and Technology, 2019, vol. 33, pp. 5407–5413. doi: 10.1007/s12206-019-1035-1.
- Yakovlev S.P., Yakovlev S.S., Chudin V.N., Sobolev Ya.A. Shape formation and diffusion welding of structural elements. Izvestiya Tulskogo gosudarstvennogo universiteta. Tekhnicheskie nauki, 2009, no. 1-1, pp. 76–85. EDN: KGLNJZ.
- Strizhakov E.L., Batsemakin M.Yu., Neskoromnyy S.V. Conditions for quality processing and algorithm of estimation and selection of parameters of magnetic-pulse welding of lapped joints. Fizika i khimiya obrabotki materialov, 2007, no. 1, pp. 64–67. EDN: KVNXST.
- Strizhakov E.L., Neskoromny S.V., Ageev S.O., Lemeshev S.V. Development of discharge-pulsed equipment for applied studies of magnetic-pulsed welding processes. Welding International, 2016, vol. 30, no. 10, pp. 813–816. doi: 10.1080/09507116.2016.1148409.